A dynamic biasing of a transmitter chip is disclosed. The transmitter chip comprises a variable gain amplifying stage, a biasing stage, a phase shifting stage, and a mixing stage. In response to a voltage control signal and a voltage intermediate frequency signal, the variable gain amplifying stage provides a current drive signal and a DC current control signal. While an ampere level of the DC component of the current drive signal and an ampere level of the DC current control signal vary as a function of any variations in the voltage control signal as well as any variation in the temperature, process performance, and supply power of the transmitter chip, a ratio of the ampere level of a DC component of the current drive signal to the ampere level of the DC current control signal is constant. The current drive signal and the DC current control signal establish the dynamic biasing block in a current mode of operation that maintains a constant gain of the mixing stage.
Legal claims defining the scope of protection, as filed with the USPTO.
1. A variable gain amplifying stage in a transmitter chip, said variable gain amplifying stage comprising: a first circuit operable to provide a current drive signal in response to a reception of a voltage control signal and voltage intermediate frequency signal by said variable gain amplifying stage, said current drive signal having an AC current component and a DC current component; a second circuit operable to provide a DC current control signal in response to a reception of said voltage control signal by said variable gain amplifying stage; and wherein a ratio of a first ampere level of said DC current component of said current drive signal to a second ampere level of said DC current control signal is constant.
2. The variable gain amplifying stage of claim 1 , wherein said second circuit is a replica of said first circuit.
3. The variable gain amplifying stage of claim 1 , wherein means for adjusting said ampere level of said DC current component of said current drive signal and said ampere level of said DC current control signal in response to any variation in a voltage level of said voltage control signal.
4. The variable gain amplifying stage of claim 1 , wherein means for adjusting said ampere level of said DC current component of said current drive signal and said ampere level of said DC current control signal in response to any variation in a temperature of the transmitter chip.
5. The variable gain amplifying stage of claim 1 , wherein means for adjusting said ampere level of said DC current component of said current drive signal and said ampere level of said DC cuurrent control signal in response to any variation in a processing performance of the transmitter chip.
6. The variable gain amplifying stage of claim 1 , wherein means for adjusting said ampere level of said DC current component of said current drive signal and said ampere level of said DC current control signal in response to any variation in a supply power of said transmitter chip.
7. A transmitter chip, comprising: a variable gain amplifying stage operable to provide a current drive signal and a DC current control signal, said DC current drive signal having an AC current component and a DC current component; a biasing stage operable to provide a first DC current biasing signal in response to a reception of said DC current control signal; and wherein a first ratio of a first ampere level of said DC current component of said current drive signal to a second ampere level of said DC current control signal is constant.
8. The transmitter chip of claim 7 , wherein said variable gain amplifying stage includes means for adjusting said ampere level of said DC current component of said current drive signal and said ampere level of said DC current control signal in response to any variation in a voltage level of said voltage control signal.
9. The transmitter chip of claim 7 , wherein said variable gain amplifying stage includes means for adjusting said ampere level of said DC current component of said current drive signal and said ampere level of said DC current control signal in response to any variation in a temperature of the transmitter chip.
10. The transmitter chip of claim 7 , wherein said variable gain amplifying stage includes means for adjusting said ampere level of said DC current component of said current drive signal and said ampere level of said DC current control signal in response to any variation in a processing performance of the transmitter chip.
11. The transmitter chip of claim 7 , wherein said variable gain amplifying stage includes means for adjusting said ampere level of said DC current component of said current drive signal and said ampere level of said DC current control signal in response to any variation in a supply power of said transmitter chip.
12. The transmitter chip of claim 7 , wherein a second ratio of said second ampere level of said DC current control signal to a third ampere level of said first DC biasing current signal is constant.
13. The transmitter chip of claim 7 , further comprising: a phase shifting stage operable to provide a current intermediate frequency signal in response to a reception of said DC current drive signal and said first DC biasing current signal.
14. The transmitter chip of claim 13 , further comprising: a mixing stage; wherein said biasing stage is further operable to provide a second DC biasing signal in response to a reception of said DC current control signal; and wherein said mixing stage is operable to provide a current radio frequency signal in response to a reception of said current intermediate frequency signal and said second DC current biasing signal.
15. The transmitter chip of claim 14 , wherein a second ratio of said second ampere level of said DC current control signal to a third ampere level of said second DC biasing current signal is constant.
16. The transmitter chip of claim 14 , wherein a gain of said mixing stage is constant.
17. A method for dynamically biasing a transmitter chip, said method comprising: generating a current drive signal in response to a reception of a voltage control signal and a voltage intermediate frequency signal, said current drive signal having an AC current component and a DC current component; and generating a DC current control signal in response to a reception of said voltage control signal, wherein a first ratio of a first ampere level of said DC component of said DC current drive signal to a second ampere level of said DC current control signal is constant.
18. The method of claim 17 , further comprising: generating a first DC current biasing signal in response to a generation of said DC current control signal, where a second ratio of said second ampere level of said DC current control signal to a third ampere level of said DC current biasing signal is constant.
19. The method of claim 18 , further comprising: generating a current intermediate frequency signal in response to a generation of said fist DC current drive signal; generating a second DC current biasing signal in response to a generation of said DC current control signal; and generating a current radio frequency signal in response to a generation of said current intermediate frequency signal said and said second DC current biasing signal.
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April 6, 2001
May 3, 2005
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